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International Journal of Scientific & Engineering Research, Volume 3, Issue 11, November-2012ISSN 2229-5518
IJSER © 2012http://www.ijser.org
The Paleocene – Early Eocene ForaminiferalBiostratigraphy of Eastern Dahomey Basin,
SW NigeriaOkosun, E. A. and Alkali, Y. B.
Abstract - The foraminiferal biostratigraphy of the Paleocene – early Eocene strata of SW Nigeria which represents the eastern Dahomeybasin has been studied from four boreholes and two outcrops. A fairly diverse planktic and benthic foraminiferal assemblage wasrecovered.Six planktic biozones comprising Praemurica pseudobulloides, P. inconstans, Morozovella angulata, Globanomalinapseudomenardii, Morozovella velascoensis and M. subbotinae were identified. Two benthic concurrent range zones, Anomalinoidesuboniferus - Eponides pseudoelevatus and Planulina oyae and Uvigerina hourcqi have been identified. These biozones will serve as usefulcorrelation tools in the West African coastal and inland sedimentary basins.
Index Terms: Benthic, Biozones, Eastern Dahomey, Foraminiferal biostratigraphy, Paleocene, Planktic , SW Nigeria
—————————— ——————————
1 INTRODUCTIONHE boreholes and quarry section studied are in south
western Nigeria (fig. 1) which represents the eastern Da-
homey basin. The Gbekebo borehole is located on the
Okitipupa ridge on the western flank of the Niger delta. The
Araromi and Gbekebo boreholes penetrated the Cretaceous
and Tertiary strata while other two boreholes BH No’s 4925
and 1582 only penetrated part of the Tertiary sequence.
Several workers have studied the geology and biostratigraphy
of the Paleocene sequence in southwestern Nigeria [2],[ 3], [4],
[5],[ 6], [7], [8],[9] [10], [11], [12], [13], [14], [15], [16], and [17].
And the objective of this study is to undertake a foraminiferal
biostratigraphic study of the Paleocene – early Eocene strata of
the Eastern Dahomey basin.
1.1 LITHOSTRATIGRAPHYThe Paleocene – Eocene stratigraphic units in SW Nigeria
comprises of Araromi, Ewekoro, Oshosun Formations and
Imo Shale (Table 1 below).
1.1.1 Araromi FormationThe formation comprises of dark grey to black shale,
shelly shale, sandy black shale and thin intercalations of lime-
stones and sandstone [15], [16]. This formation was found in
Araromi – 1 and Gbekebo – 1 borehole at 446 m – 583 m and
880 m – 1093 m respectively. The unit is equivalent to the Ara-
romi Shale of [19] and the Nkporo Shale of [21]. The formation
has an early Paleocene (Danian) age in SW Nigeria [17].
1.1.2 Imo ShaleThe Imo Shale is composed of grey, dark-grey and
black shale with occasional white to brown sands [17]. Glau-
conite occurs sporadically in the formation. The shale is thinly
laminated, and generally fissile and locally calcareous. The
black shale facies was not encountered in the Gbekebo – 1 and
Araromi – 1 boreholes, it appears to be restricted to the north-
ern (inland) part of the basin. A maximum formation thickness
of 178.4 m was reported for the northern part of the basin
while 429m (from 421 m to 850 m) and 240 m (212 m to 454 m)
have been reported from Gbekebo – 1 and Araromi – 1 bore-
hole respectively from the coastal area [17].
1.1.3 Ewekoro FormationThe formation is exposed at the Larefag WAPCO
quarries at Ewekoro and Shagamu. At the Ewekoro quarry,
the unit comprises of the following lithofacies:
T
International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
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Fig. 1: Location map showing study area and the distribution of Paleocene-Eocene Sediments in Southern Nigeria
Table 1: Correlation of early Tertiary Formations in Nigeria
International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
IJSER © 2012http://www.ijser.org
Basal sandy fossiliferous limestone, massive limestone nodu-
lar limestone and an uppermost glauconitic shale bed. The
exposed section of the formation at the Shagamu quarry is
composed of a basal nodular limestone bed that is followed by
grey laminated shale, massive limestone, black shale and an
uppermost massive fossiliferous limestone.
The formation was only encountered in the inland part of the
basin. It was not found in the Araromi-1 and Gbekebo-1 bore-
holes. A maximum thickness of 47m has been reported for the
formation. The base and top of the unit are marked by black
and grey shale respectively [21].
1.1.4 Oshosun FormationThe formation comprises of green, greenish- grey or
beige clay and shale with interbeds of sand. The shale is usual-
ly thickly laminated, calcareous and glauconitic. The associat-
ed sand is whitish, light brown or brownish grey in colour; it
is predominantly medium to coarse grained with some fine
grained horizons. The quartz grains are round, fine and clear,
the sand is usually poorly sorted. Vesicular, nodular or com-
pact phosphorites occur sporadically in the formation [17].
Thin limestone or marl beds are locally present in the for-
mation [20], [19], [22], [23], [17] the formation becomes arena-
ceous and calcareous towards the top and base respectively.
Vertical and laterals lithofacies variations are common. A
maximum thickness if 101.5m was reported for the formation
[21].
2 MATERIALS AND METHODSSamples for the study were collected from Araromi—
1 borehole (GSN), Gbekebo borehole (GSN), Akinside bore-
hole (GSN 1582) Borehole No 4925, Ewekoro and Shagamu
limestone quarries. The samples were collected at 2-3 meter
intervals from the borehole core. The representatives’ lithofa-
cies samples were collected from the quarry faces.
The samples were disaggregated in a solution of 10%
H2O2 overnight and boiled in water with a pinch of soda
ash. They were then washed through a 63µm sieve. The wash-
ing procedure was repeated until foraminifera with clean sur-
faces were obtained. All the foraminifera recovered from the
residue were counted and studied under the microscope. Ge-
neric classification was based on [28] [17] and other relevant
foraminifera literature.
The species identification was based mainly on [23].
The species identification was based mainly on [23].
3 RESULTS3.1 BiostratigraphyA fairly diverse foraminiferal assemblage of planktic and ben-
thic species was recovered in this study. Their stratigraphic
distribution is illustrated in figs. 2-5. Majority of the foraminif-
eral species are illustrated in plates 1-3. From the first and last
appearances of diagnostic species, six planktic foraminiferal
biozones were recognized form the early Paleocene to the ear-
ly Eocene (Table 2). The planktic foraminiferal zonal schemes
adopted here are those by [23] and [25] for the early Tertiary.
Two benthic foraminiferal biozones were recognized. The
proposed biozones are arranged from base to top.
3.2 Planktic Foraminiferal ZonesParasubbotina pseudobulloides Zone
P1a + P1b sub zones [25]
Age: Earliest Paleocene
Author: [26]
The partial range of the index taxon from its FAD to the LAD
of Praemurica trinidadensis (Bolli) was used to define the zone
(30). The upper boundary is also correlated to the FAD of
Praemurica inconstans (Subbotina) according to [25]. Praemurica
trinidadensis (Bolli) was not found in the study area.
The dominant species in this zone are Subbotina triloculinoides
(Plummer), Globanomalina compressa (Plummer), Globoconusa
danbjergensis (Bronnimann) and Eoglobigerina trivialis. The P.
pseudobulloides zones occur in the Araromi – 1 and Gbekebo – 1
borehole (Fig. 2 & 3).
International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
IJSER © 2012http://www.ijser.org
Table 2. Planktic and benthic foraminiferal biostratigraphy of the eastern Dahomey Basin and correlation with the inter-reginal schemes.
3.2.1 Praemurica inconstans ZoneP. trinidadensis Zone [27]
Age: Early Paleocene
Author: [25]
This zone was defined by [25] as sub-zone Pic based on the
FAD of P. inconstans (Subbotina) to the FAD of Praemurica uci-
nata (Bolli). The dominant species in this zone are Parasobbotina
pseudobulloides (Plummer), Subbotina triloculinoides (Plum-
mer) and Globanomalina compressa (Plummer). The P. inconstans
Zone occurs only in Araromi – 1 borehole. The P. ucinata
Zones of [27] and [25] was not encountered in this study.
3.2.2 Morozovella angulata ZoneP3a subzone [25]
Age: Late Paleocene
Author: Hillebrandt [28]
This zone has been defined as the partial range of M. angulata
(White) from its FAD to the FAD of Igorina pusilla (Bolli). The
top of this zone was defined by [25] based on the FAD of Igor-
ina albeari (Cushman and Bermudez) instead of I. pusilla. The
dominant species in this zone include Morozovella acuta
(Toulmin) M. aqua (Cushman and Renz), Globigerina linaperta
(Finlay) Globorotalia haynesis (Fayose) and Acarinina primitiva
(Finlay). The M. angulata Zone occurs in Araromi – 1, Gbekebo
– 1, Akinside (BH 1582) boreholes. The zone also occurs in
borehole No 4925 Ewekoro and Shagamu limestone quarries.
3.2.3 Globanomalina pseudomenardii ZoneP4 zone [25]
Age: Late Paleocene
Author: [25]
The Globanomalina pseudomenardii Zone is a taxon range zone
defined by the total range of it’s nominate species. The charac-
teristic species include Acarinina primitiva, Morozovella africana,
M. costteina, Globigerina occlusa, Acarinina
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Fig. 2: Stratigraphic distribution of Araromi Borehole [GSN BH 1131]
10 SPECIMENS & ABOVE1 – 10 SPECIMENS
LIMESTONE
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Fig.3. Stratigraphic distribution of foraminifera in Gbekebo Borehole [GSN/BH 1132], legend as in fig. 2
International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
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pseudotopilensis, M. angulata (white), M. acuta (Toulmin), M.
aqua (Cushman and Renz), M.Velascoensis (Cushman). The G.
pseudomenardii Zone occurs in Araromi – 1 borehole and the
Shagamu limestone quarry.
3.2.4 Morozovella velascoensis ZoneP5 zone [25]
Age: Late Paleocene
Author: [25]
This zone was defined as the partial range of the nominate
taxon from the last appearance datum (LAD) of Globanomalina
pseudomenardii (Bolli) to the LAD of Morozovella velascoensis
(Cushman). The characteristic species include Morozovella for-
mosa, M. acuta, M. aequa, Acarinina primtiva. The Morozovella
velascoensis zone occurs in Araromi-1 borehole and Shagamu
limestone quarry.
3.2.5 Morozovella subbotinae ZoneM. edgari zone [27]
Age: Earliest Eocene
The M. subbotinae zone is an interval zone that was defined
between the LAD of Morozovella velascoensis (Cushman) to the
FAD of M. aragonensis (Nutal). The Paleocene / Eocene
boundary lies near type lower boundary of the M. subbotinae
zone which is placed at the LAD of Morozovella .velascoensis
(Cushman). The characteristic species include M. gracilis (Bol-
li), Globorotalia cerroazulensis (Cole) Acarinina soldadoensis
(Bronnimann), A. primitiva (Finlay), Subbotina linaperta (Finlay)
The M. subbotinae zone occurs in Araromi – 1 bore-
hole. Although the nominate taxon M. subbotinae (Morozova)
was not encountered in Akinside borehole (BH1582) and BH
4925 the presence of the following
species Acarinina pseudotopilensis A. pentacamerata (Subbotina),
A.tribulosa (Loeblich and Tappan), Globorotalia wilcoxensis
(Cushman and Ponto) and A. broedemani (Cushman and Ber-
mudez), suggest its presence (fig 4-5).
Author: [25]
Fig. 4: Stratigraphic distribution of foraminifera in BH 4925, legend as in fig. 2
1-10 Specimens
International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
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1-10 SpecimensFig. 5 Stratigraphic distribution of foraminifera in Akinside Borehole [ BH 1582] Legend as in fig. 2
3.3 Benthic Foraminiferal ZonesThe benthic foraminiferal species recovered in this
study are long ranging. Two concurrent range zones, one for
the Paleocene and the second for the early Eocene have been
identified. The concurrent-range-zones comprises of 2 over-
lapping species ranges which have time significance and pos-
sibilities of geographic extensions. This is in consonance with
the international stratigraphic guide [30].
3.3.1 Anomalinoides umboniferus – Epondespseudoelevatus Zone
Age: Early and late Paleocene
Author: [14]
This zone was defined by the concurrent range of the nomi-
nate taxa Anomalinoides umboniferus (Schwager) and Eponides
pseudoelevatus Graham, de Klasz & Rerat. The base of the
zone coincides with the Cretaceous Tertiary boundary which
is marked by the extinction of majority of the Maastrichtian
species. The top is also defined by the disappearance of the
typical Paleocene species and the nominate taxa [14]. The zone
embraces the Paleocene and includes the Imo shale and
Ewekoro Formation in the present study.
The characteristic species include: Anomalinoides midwayensis
(Plummer), Gavelinella pachysuturalis
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3.3.2 Planulina oyae-Uvigerina hourcqi ZoneAge: Early Eocene
Author: [14]
The zone is defined by the overlapping ranges of the two nom-
inate taxa Planulina oyae Reyment and Uvigerina hourcqi (Gra-
ham, de Klasz and Rerat). Base of the zone is marked by the
abrupt appearance of the nominate taxa and other Eocene ben-
thic foraminiferal species and the presence of endemic West
African Eocene species. The characteristic species include Sa-
grina circumspinosa (De Klasz & Rerat), Eponides africana De
Klasz & Rerat, Hopkinsina danvillensis Howe & Wallace, Uviger-
ina jacksonensis Cushman. The disappearance of the above taxa
characterises the top of the zone.
The zone embraces the Eocene but was found in this
study in the Early Eocene. It occurs in the Oshosun Formation.
4 DISCUSSION AND CONCLUSION The Paleocene benthic foraminifera from the eastern Daho-
mey basin recorded in this study shows strong affinity to the
Midway type fauna of the Midway Formation of Gulf coastal
plain of North America [32] some species of the assemblage
are common to the Paleocene of Tunisia [32], Libya and [33]
and [34]. The Paleocene benthic foraminifera from the Sokoto
basin [21] Shows similarity to the assemblage recorded in the
current study. Thus the two coeval assemblages belong to dif-
ferent biogeography provinces. This does not support the
view of a union and faunal exchange between the Tethys and
the South Atlantic ocean during the Paleocene.
The six planktic foraminifera zones can be correlated to the
interregional planktic foraminifera zones of [27] and [25].
Both the planktic and benthic zones will serve as useful corre-
lation tools in the coastal and inland basins of West Africa.
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International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
IJSER © 2012http://www.ijser.org
era from the Ewekoro Type Section (Paleocene) Nigeria
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International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
IJSER © 2012http://www.ijser.org
E. A. Okosun is currently a Professor in Department
of Geology, Federal University of Technology, Minna.
Nigeria
Email : [email protected]
Y. B. Alkali is currently lecturing in Department of
Geology, Federal University of Technology ,Minna ,
Nigeria.
E-mail : [email protected]
International Journal of Scientific & Engineering Research Volume 3, Issue 11, November-2012ISSN 2229-5518
IJSER © 2012http://www.ijser.org
APPENDIX A
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APPENDIX B
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APPENDIX C